CAMBRIDGE, MA--(Marketwired - Nov 18, 2013) - Sand 9, Inc. today became the first micro-electromechanical systems (MEMS) company to achieve the stringent low-noise, high-stability and harsh environmental requirements for precision timing in communications infrastructure, industrial and military applications. As the first product based on Sand 9's patented Temperature Compensated MEMS Oscillator (TCMO™) platform -- which features the industry's highest-performance MEMS architecture -- the TM651 offers system designers a better alternative to existing quartz and MEMS-based timing solutions.

The TM651 exceeds the performance of quartz in several ways, offering exceptional activity dip suppression, superior shock and vibration immunity, and outstanding electromagnetic interference (EMI) protection. The end result is an extremely reliable timing source that enables better system design, quality, reliability and performance. The TM651 also provides 100 times better electromechanical coupling over conventional electrostatic MEMS architectures. This produces a significantly higher signal-to-noise (SNR) ratio, supporting far greater performance than any other MEMS solution.

"While every electronic application needs a timing device in order to function, quartz-based products have been historically slow to evolve," said Vince Graziani, CEO, Sand 9. "The TM651 is a major step forward in that evolution. It delivers greater precision and higher reliability than competitive solutions, which is critically important for large communications infrastructure systems, such as data center switches, Ethernet communications and point-to-point radios -- applications for which packet loss or loss of signal is simply not acceptable. These attributes are equally crucial for thousands of different high-value industrial and military applications."

Sand 9 is working closely with a number of leading analog semiconductor partners to provide reference designs for their synthesizer and timing products. Peter Real, vice president, High Speed Products and Technology, Analog Devices, commented: "As a leading supplier into communications infrastructure, industrial and military markets, Analog Devices is committed to exploring technologies that may improve the experience of our customers. Having initially invested in Sand 9 late last year, we are pleased to see them launch their first precision MEMS timing product."

About the TM651The TM651 is a voltage controlled and temperature compensated MEMS oscillator with differential output, high output frequency, low jitter and high stability, making it ideally suited for precision timing applications. Its architecture consists of a piezoelectric MEMS resonator hermetically bonded to an RF ASIC containing oscillator and temperature compensation circuitry.

Technical Features and Benefits

125 MHz high frequency with differential output -- offers more than 50% lower current drain relative to comparable quartz products

AvailabilityThe TM651 is currently sampling to lead customers, and will be ramping to mass production in Q1 2014. It is available in an industry-standard 3.2 mm x 2.5 mm x 1.2 mm LGA package. To order or receive technical information on the TM651, please visit: www.sand9.com or contact: info@sand9.com.

About Sand 9Founded in 2007 in Cambridge, MA, Sand 9 is a pioneer of precision MEMS timing products based on piezoelectric actuation. Targeting a $4+B market opportunity with its MEMS timing products -- which serve wireless and wired systems in communications, industrial, military and mobile markets -- Sand 9's products outperform both legacy quartz timing devices and other MEMS-based solutions. Sand 9's MEMS timing products enhance quality and performance, simplify system design, and promote space and power savings in integrated electronic systems. For more information on Sand 9, please contact us via phone: +617.453.2451, email: info@sand9.com or web: www.sand9.com.

Sand 9 is a registered trademark and TCMO is a trademark of Sand 9, Inc. All other product and company names are trademarks or registered trademarks of their respective holders.